Lysine and threonine metabolism are subject to complex patterns of regulation in Arabidopsis

To study the regulation of lysine and threonine metabolism in plants, we have transformed Arabidopsis thaliana with chimeric genes encoding the two bacterial enzymes dihydrodipicolinate synthase (DHPS) and aspartate kinase (AK). These bacterial enzymes are much less sensitive to feedback inhibition by lysine and threonine than their plant counterparts. Transgenic plants expressing the bacterial DHPS overproduced lysine, but lysine levels were quite variable within and between transgenic genotypes and there was no direct correlation between the levels of free lysine and the activity of DHPS. The most lysine-overproducing plants also exhibited abnormal phenotypes. However, these phenotypes were detected only at early stages of plant growth, while at later stages, new buds emerged that looked completely normal and set seeds. Wild-type plants exhibited relatively high levels of free threonine, suggesting that in Arabidopsis AK regulation may be more relaxed than in other plants. This was also supported by the fact that expression of the bacterial AK did not cause any dramatic elevation in this amino acid. Yet, the relaxed regulation of threonine synthesis in Arabidopsis was not simply due to a reduced sensitivity of the endogenous AK to feedback inhibition by lysine and threonine because growth of wild-type plants, but not of transgenic plants expressing the bacterial AK, was arrested in media containing these two amino acids. The present results, combined with previous studies from our laboratory, suggest that the regulation of lysine and threonine metabolism is highly variable among plant species and is subject to complex biochemical, physiological and environmental controls. The suitability of these transgenic Arabidopsis plants for molecular and genetic dissection of lysine and threonine metabolism is also discussed.     

Concerted regulation of lysine and threonine synthesis in tobacco plants expressing bacterial feedback-insensitive aspartate kinase and dihydrodipicolinate synthase

The essential amino acids lysine and threonine are synthesized in higher plants by two separate branches of a common pathway. This pathway is primarily regulated by three key enzymes, namely aspartate kinase (AK), dihydrodipicolinate synthase (DHPS) and homoserine dehydrogenase (HSD), but how these enzymes operate in concert is as yet unknown. Addressing this issue, we have expressed in transgenic tobacco plants high levels of bacterial AK and DHPS, which are much less sensitive to feedback inhibition by lysine and threonine than their plant counterparts. Such expression of the bacterial DHPS by itself resulted in a substantial overproduction of lysine, whereas plants expressing only the bacterial AK overproduced threonine. When both bacterial enzymes were expressed in the same plant, the level of free lysine exceeded by far the level obtained by the bacterial DHPS alone. This increase, however, was accompanied by a significant reduction in threonine accumulation compared to plants expressing the bacterial AK alone. Our results suggested that in tobacco plants the synthesis of both lysine and threonine is under a concerted regulation exerted by AK, DHPS, and possibly also by HSD. We propose that the balance between lysine and threonine synthesis is determined by competition between DHPS and HSD on limiting amounts of their common substrate 3-aspartic semialdehyde, whose level, in turn, is determined primarily by the activity of AK. The potential of this molecular approach to increase the nutritional quality of plants is discussed.     

Threonine Overproduction in Transgenic Tobacco Plants Expressing a Mutant Desensitized Aspartate Kinase of Escherichia coli

In higher plants, the synthesis of the essential amino acid threonine is regulated primarily by the sensitivity of the first enzyme in its biosynthetic pathway, aspartate kinase, to feedback inhibition by threonine and lysine. We aimed to study the potential of increasing threonine accumulation in plants by means of genetic engineering. This was addressed by the expression of a mutant, desensitized aspartate kinase derived from Escherichia coli either in the cytoplasm or in the chloroplasts of transgenic tobacco (Nicotiana Tabacum cv Samsun NN) plants. Both types of transgenic plants exhibited a significant overproduction of free threonine. However, threonine accumulation was higher in plants expressing the bacterial enzyme in the chloroplast, indicating that compartmentalization of aspartate kinase within this organelle was important, although not essential. Threonine overproduction in leaves was positively correlated with the level of the desensitized enzyme. Transgenic plants expressing the highest leaf aspartate kinase activity also exhibited a slight increase in the levels of free lysine and isoleucine, both of which share a common biosynthetic pathway with threonine, but showed no significant change in the level of other free amino acids. The present study proposes a new molecular biological approach to increase the limiting content of threonine in higher plants.     

Seed-specific expression of a bacterial desensitized aspartate kinase increases the production of seed threonine and methionine in transgenic tobacco

In order to study the regulation of threonine and methionine synthesis in plant seeds, tobacco plants were transformed with a chimeric gene containing the coding DNA sequence of a mutant lysC gene from Escherichia coli fused to a promoter from a phaseolin seed storage protein gene. The bacterial mutant lysC gene codes for aspartate kinase (AK) which is desensitized to feedback inhibition by lysine and threonine. Increased AK activity, compared with control non-transformed plants, was detected in seeds but not in leaves, roots and flowers of the transgenic plants. This expression was accompanied by a significant increase in the levels of free threonine and methionine in the seed. The level of these amino acids also correlated positively with the levels of the bacterial enzyme. No alteration in plant phenotype and 'average seed weight' was observed in any of the transgenic plants, indicating that plant growth and seed development were normal. This study demonstrates, for the first time, that the threonine and methionine biosynthetic pathways are active in plant seeds. Thus, targeting of the production of favorable biosynthetic enzymes to plant seeds may represent a desirable molecular approach for production of crop plants with a more balanced nutritional quality.     

Metabolically engineered soybean seed with enhanced threonine levels: biochemical characterization and seed‐specific expression of lysine‐insensitive variants of aspartate kinases from the enteric bacterium Xenorhabdus bovienii

Threonine (Thr) is one of a few limiting essential amino acids (EAAs) in the animal feed industry, and its level in feed rations can impact production of important meat sources, such as swine and poultry. Threonine as well as EAAs lysine (Lys) and methionine (Met) are all synthesized via the aspartate family pathway. Here, we report a successful strategy to produce high free threonine soybean seed via identification of a feedback‐resistant aspartate kinase (AK) enzyme that can be over‐expressed in developing soybean seed. Towards this goal, we have purified and biochemically characterized AK from the enteric bacterium Xenorhabdus bovienii (Xb). Site‐directed mutagenesis of XbAK identified two key regulatory residues Glu‐257 and Thr‐359 involved in lysine inhibition. Three feedback‐resistant alleles, XbAK_T359I, XbAK_E257K and XbAK_E257K/T359I, have been generated. This study is the first to kinetically characterize the XbAK enzyme and provide biochemical and transgenic evidence that Glu‐257 near the catalytic site is a critical residue for the allosteric regulation of AK. Furthermore, seed‐specific expression of the feedback‐resistant XbAK_T359I or XbAK_E257K allele results in increases of free Thr levels of up to 100‐fold in R₁ soybean seed when compared to wild‐type. Expression of feedback‐sensitive wild‐type AK did not substantially impact seed Thr content. In addition to high Thr, transgenic seed also showed substantial increases in other major free amino acid (FAA) levels, resulting in an up to 3.5‐fold increase in the total FAA content. The transgenic seed was normal in appearance and germinated well under greenhouse conditions.     

Engineering of the aspartate family biosynthetic pathway in barley (Hordeum vulgare L.) by transformation with heterologous genes encoding feed-back-insensitive aspartate kinase and dihydrodipicolinate synthase

In prokaryotes and plants the synthesis of the essential amino acids lysine and threonine is predominantly regulated by feed-back inhibition of aspartate kinase (AK) and dihydrodipicolinate synthase (DHPS). In order to modify the flux through the aspartate family pathway in barley and enhance the accumulation of the corresponding amino acids, we have generated transgenic barley plants that constitutively express mutant Escherichia coli genes encoding lysine feed-back insensitive forms of AK and DHPS. As a result, leaves of primary transformants (T₀) exhibited a 14-fold increase of free lysine and an 8-fold increase in free methionine. In mature seeds of the DHPS transgenics, there was a 2-fold increase in free lysine, arginine and asparagine and a 50% reduction in free proline, while no changes were observed in the seeds of the two AK transgenic lines analysed. When compared to that of control seeds, no differences were observed in the composition of total amino acids. The introduced genes were inherited in the T₁ generation where enzymic activities revealed a 2.3-fold increase of AK activity and a 4.0–9.5-fold increase for DHPS. T₁ seeds of DHPS transformants showed the same changes in free amino acids as observed in T₀ seeds. It is concluded that the aspartate family pathway may be genetically engineered by the introduction of genes coding for feed-back-insensitive enzymes, preferentially giving elevated levels of lysine and methionine.     

The expression level of threonine synthase and cystathionine-γ-synthase is influenced by the level of both threonine and methionine in <Emphasis Type="Italic">Arabidopsis</Emphasis> plants

The biosynthesis pathways of the essential amino acids methionine and threonine diverge from O-phosphohomoserine, an intermediate metabolite in the aspartate family of amino acids. Thus, the enzymes cystathionine-γ-synthase (CGS) in the methionine pathway and threonine synthase (TS), the last enzyme in the threonine pathway, compete for this common substrate. To study this branching point, we overexpressed TS in sense and antisense orientation in Arabidopsis plants with the aim to study its effect on the level of threonine but more importantly on the methionine content. Positive correlation was found not only between TS expression level and threonine content, but also between TS/threonine and CGS expression level. Plants expressing the sense orientation of TS showed a higher level of threonine, increased expression level of CGS, and a significantly higher level of S-methylmethionine, the transport form of methionine. By contrast, plants expressing the antisense form of TS showed lower levels of threonine and of CGS expression level. In these antisense plants, the methionine level increased up to 47-fold compared to wild-type plants. To study further the effect of threonine on CGS expression level, wild-type plants were irrigated with threonine and control plants were irrigated with methionine or water. While threonine increased the expression level of CGS but reduced that of TS, methionine reduced the expression level of CGS but increased that of TS. This data demonstrate that both methionine and threonine affect the two enzymes at the branching point, thus controlling not only their own level, but also the level of each other. This mechanism probably aids in keeping the levels of these two essential amino acids sufficiently high to support plant growth.     

Metabolic engineering of a complex biochemical pathway: The lysine and threonine biosynthesis as an example

The nutritional quality of crop plants is determined by their content in essential amino acids provided in food for humans or in feed for monogastric animals. Amino acid composition of crop–based diets can be improved via manipulation of the properties of key enzymes of amino acid biosynthetic pathways by mutation and transformation. We focused on the aspartate-derived amino acid pathway producing four essential amino acids: lysine, threonine, isoleucine and methionine. Genes encoding aspartate kinase (AK) and dihydrodipicolinate synthase (DHDPS) that operate as key genes of the aspartate pathway have been cloned from Arabidopsis. Genetic and molecular studies revealed that at least five different ak genes are represented. Some of them were characterized in terms of gene and promoter structure, developmental expression and regulatory properties. In the case of dhdps, two quite identical genes have been identified and characterized at expression level. Mutated genes encoding a fully feedback-insensitive form of the DHDPS enzyme were obtained from Nicotiana sylvestris and Arabidopsis. Several chimeric constructs harbouring this mutated allele under the control of constitutive or seed-specific promoters were transferred via Agrobacterium or biolistics in various plant species. In all cases, lines with significant increase of free lysine content were obtained in vegetative organs, but the impact of the transgene in seeds is limited due to the presence of an active catabolic enzyme, lysine ketoreductase. These results show that, although dealing with a complex, highly regulated pathway, the overexpression of a single gene encoding a feedback-insensitive form of the key enzyme DHDPS exerts a significant effect on the carbon flux through the aspartate pathway towards lysine production.     

Metabolic engineering and profiling of rice with increased lysine

Lysine (Lys) is the first limiting essential amino acid in rice, a stable food for half of the world population. Efforts, including genetic engineering, have not achieved a desirable level of Lys in rice. Here, we genetically engineered rice to increase Lys levels by expressing bacterial lysine feedback‐insensitive aspartate kinase (AK) and dihydrodipicolinate synthase (DHPS) to enhance Lys biosynthesis; through RNA interference of rice lysine ketoglutaric acid reductase/saccharopine dehydropine dehydrogenase (LKR/SDH) to down‐regulate its catabolism; and by combined expression of AK and DHPS and interference of LKR/SDH to achieve both metabolic effects. In these transgenic plants, free Lys levels increased up to ~12‐fold in leaves and ~60‐fold in seeds, substantially greater than the 2.5‐fold increase in transgenic rice seeds reported by the only previous related study. To better understand the metabolic regulation of Lys accumulation in rice, metabolomic methods were employed to analyse the changes in metabolites of the Lys biosynthesis and catabolism pathways in leaves and seeds at different stages. Free Lys accumulation was mainly regulated by its biosynthesis in leaves and to a greater extent by catabolism in seeds. The transgenic plants did not show observable changes in plant growth and seed germination nor large changes in levels of asparagine (Asn) and glutamine (Gln) in leaves, which are the major amino acids transported into seeds. Although Lys was highly accumulated in leaves of certain transgenic lines, a corresponding higher Lys accumulation was not observed in seeds, suggesting that free Lys transport from leaves into seeds did not occur.     

Regulation of lysine synthesis in transgenic potato plants expressing a bacterial dihydrodipicolinate synthase in their chloroplasts

The essential amino acid lysine is synthesized in higher plants by a complex pathway that is predominantly regulated by feedback inhibition of two enzymes, namely aspartate kinase (AK) and dihydrodipicolinate synthase (DHPS). Although DHPS is thought to play a major role in this regulation, the relative importance of AK is not known. In order to study this regulation, we have expressed in the chloroplasts of transgenic potato plants a DHPS derived from Escherichia coli at a level 50-fold above the endogenous DHPS. The bacterial enzyme is much less sensitive to lysine inhibition than its potato counterpart. DHPS activity in leaves, roots and tubers of the transgenic plants was considerably higher and more resistant to lysine inhibition than in control untransformed plants. Furthermore, this activity was accompanied by a significant increase in level of free lysine in all three tissues. Yet, the extent of lysine overproduction in potato leaves was significantly lower than that previously reported in leaves of transgenic plants expressing the same bacterial enzyme, suggesting that in potato, AK may also play a major regulatory role in lysine biosynthesis. Indeed, the elevated level of free lysine in the transgenic potato plants was shown to inhibit the lysine-sensitive AK activity in vivo. Our results support previous reports showing that DHPS is the major rate-limiting enzyme for lysine synthesis in higher plants, but they suggest that additional plant-specific regulatory factors are also involved.     

Molecular aspects of methionine biosynthesis

Methionine, lysine and threonine are essential amino acids required in the diets of non-ruminant animals. Major crops, such as corn, soybean and rice, are low in one or more of these amino acids. Currently, these amino acids are supplemented to animal feed to allow optimal growth--a costly process for farmers and consumer, therefore there is a great deal of interest in increasing essential amino acids in crops. The metabolism of methionine in plants is linked to the regulation of the aspartate pathway and is important for plant growth. In recent years, several key steps of this pathway have been identified at the molecular level, enabling us to initiate transgenic approaches to engineer the methionine content of plants.     

High threonine producer mutant ofNicotiana sylvestris (Spegg. and Comes)

Summary Mutagenesis and the subsequent selection of mesophyll diploid protoplasts ofNicotiana sylvestris on growth inhibitory concentrations of lysine plus threonine has led to the isolation of an LT-resistant mutant. Regeneration of this line (RLT 70) and analysis of its descendants demonstrated the dominant monogenic nuclear character of the resistance gene, further namedak-LT1. When the inhibition properties of aspartate kinase were examined in the homozygous mutant, lysine-sensitive activity could no longer be detected. In comparison, 70%–80% of the wild-type enzyme activity was usually inhibited by lysine, and the rest by threonine. Evidence for the existence of at least two AK isoenzymes was obtained by ion-exchange chromatography, where two peaks of activity could be detected: the first one to be eluted is lysine sensitive, and the second one threonine sensitive. One consequence of the altered regulation of AK in the mutant was the enhanced production of soluble threonine. Threonine accumulation was observed to occur throughout the life cycle of the mutant plant as well as in its different organs. In particular, leaves exhibited a 45-fold increment of soluble threonine, which corresponds to a 13-fold increase in total threonine: almost one-third of the total amino acids was free and proteinbound threonine. In RLT 70 seeds, 20% of the free amino acid pool was in the form of threonine (70-fold accumulation compared to the wild type), and total threonine content was increased five fold. As a general rule, the other amino acids were also more abundant in RLT 70 seeds, such that the total of amino acids present was between two to four times higher, but in contrast with the situation encountered in leaves, this was also due to a higher protein-bound amino acid content.     

Lysine-insensitive aspartate kinase in two threonine-overproducing mutants of maize

Aspartate kinase (AK; EC 2.7.2.A) catalyzes the first reaction in the biosynthesis pathway for aspartate-derived amino acids in plants. Aspartate kinase was purified from wildtype and two maize (Zea mays L.) genotypes carrying unlinked dominant mutations,Ask LT19 andAsk2 -LT20, that conferred overproduction of threonine, lysine, methionine and isoleucine. The objective of this investigation was to characterize the AKs from mutant and wildtype plants to determine their role in regulating the synthesis of aspartate-derived amino acids in maize. Kernels of the homozygousAsk2 mutant exhibited 174-, 10-, 13- and 2-fold increases in, in this sequence, free threonine, lysine, methionine and isoleucine, compared to wildtype. In wildtype maize, AK was allosterically feedback-inhibited by lysine with 10 μMl-lysine required for 50% inhibition. In contrast, AK purified from the isogenic heterozygousAsk and homozygousAsk2 mutants required 25 and 760 μM lysine for 50% inhibition, respectively, indicating thatAsk andAsk2 were separate structural loci for lysine-regulated AK subunits in maize. Further characterization of purified AK from the homozygous mutantAsk2 line indicated altered substrate and lysine inhibition kinetics. The apparent Hill coefficient was 0.7 for the mutantAsk2 AK compared with 1.6 for the wildtype enzyme, indicating that the mutant allele conferred the loss of a lysinebinding site to the mutant AK. Lysine appeared to be a linear noncompetitive inhibitor ofAsk2 AK with respect to MgATP and an uncompetitive inhibitor with respect to aspartate compared to S-parabolic, I parabolic noncompetitive inhibition of wildtype AK. Reduced lysine sensitivity of theAsk2 gene product appeared to reduce the lysine inhibition of all of the AK activity detected in homozygousAsk2 plants, indicating that maize AK is a heteromeric enzyme consisting of the two lysine-sensitive polypeptides derived from theAsk andAsk2 structural genes. Scientific paper No. 17419, Minnesota Agricultural Experiment Station projects No. 0302-4813-56 and No. 0302-4818-32 This research was supported in part by the U.S. Depatment of Agriculture Competitive Research Grants Office grant 86-CRCR-1-2019. The authors are grateful to Charles Grissom for providing the computer programs in an IBM-PC format.     

Increased lysine synthesis in tobacco plants that express high levels of bacterial dihydrodipicolinate synthase in their chloroplasts

A major nutritional drawback of many crop plants is their low content of several essential amino acids, particularly lysine. The biosynthesis of lysine in plants is regulated by several feedback loops. Dihydrodipicolinate synthase (DHPS) from Escherichia coli, a key enzyme in lysine biosynthesis, which is considerably less sensitive to lysine accumulation than the endogenous plant enzyme has been expressed in chloroplasts of tobacco leaves. Expression of the bacterial enzyme was accompanied by a significant increase in the level of free lysine. No increase in protein-bound lysine was evident. Free lysine accumulation was positively correlated with the level of DHPS activity in various transgenic plants. Compartmentalization of DHPS in the chloroplast was essential for its participation in lysine biosynthesis as no lysine overproduction was obtained in transgenic plants that expressed the bacterial enzyme in the cytoplasm. The elevated level of free lysine in the transgenic plants was sufficient to inhibit, in vivo, a second key enzyme in lysine biosynthesis, namely, aspartate kinase, with no apparent influence on lysine accumulation. The present report not only provides a better understanding of the regulation of lysine biosynthesis in higher plants but also offers a new strategy to improve the production of this essential amino acid.     

Mechanism of Concerted Inhibition of α2β2-type Hetero-oligomeric Aspartate Kinase from Corynebacterium glutamicum

Aspartate kinase (AK) is the first and committed enzyme of the biosynthetic pathway producing aspartate family amino acids, lysine, threonine, and methionine. AK from Corynebacterium glutamicum (CgAK), a bacterium used for industrial fermentation of amino acids, including glutamate and lysine, is inhibited by lysine and threonine in a concerted manner. To elucidate the mechanism of this unique regulation in CgAK, we determined the crystal structures in several forms: an inhibitory form complexed with both lysine and threonine, an active form complexed with only threonine, and a feedback inhibition-resistant mutant (S301F) complexed with both lysine and threonine. CgAK has a characteristic α₂β₂-type heterotetrameric structure made up of two α subunits and two β subunits. Comparison of the crystal structures between inhibitory and active forms revealed that binding inhibitors causes a conformational change to a closed inhibitory form, and the interaction between the catalytic domain in the α subunit and β subunit (regulatory subunit) is a key event for stabilizing the inhibitory form. This study shows not only the first crystal structures of α₂β₂-type AK but also the mechanism of concerted inhibition in CgAK.     

Additive effects of the feed-back insensitive bacterial aspartate kinase and the Brazil nut 2S albumin on the methionine content of transgenic narbon bean (Vicia narbonensis L.)

So far two different strategies for engineering high methionine (Met) grain legumes were followed separately in several laboratories: a) The transfer of foreign genes encoding Met-rich proteins, and b) the engineering of Met biosynthesis pathways. In some cases a down regulation of the formation of endogenous sulfur-containing compounds was observed due to the expression of Met-rich foreign proteins. Since this might result from competition of the foreign protein with endogenous compounds for limited Met supply both strategies were combined in the present work. Double transformants of narbon bean (Vicia narbonensis L.) were generated which express seed-specifically the Met-rich Brazil nut 2S albumin (BNA) as well as a feed-back insensitive bacterial aspartate kinase (AK) known to stimulate Met biosynthesis in transgenic tobacco seeds. In order to produce double transformants a homozygous transgenic BNA line of narbon bean was either retransformed with the AK gene or crossed with an AK line. For the first time the influence of a deregulated AK on amino acids of the aspartate pathway was studied in seeds of a transgenic legume. Effects of expressing the foreign genes on inorganic sulphate, free and protein-bound Met and other amino acids of the aspartate pathway as well as on free sulphhydryl compounds of mature seeds were analysed. AK lines had 10 to 12 percent and the BNA line 80 percent increased Met in mature seeds. Double transformants showed additive but not synergistic effects of the expression of AK and BNA gene on seed Met. In their mature seeds protein-bound Met reached levels 2.0 to 2.4 times higher than in the wildtype. The Met level of best line corresponds approximately to the FAO standard for Met in a nutritionally balanced protein for human food or for feeding monogastric animals.     

Regulatory mechanisms after short‐ and long‐term perturbed lysine biosynthesis in the aspartate pathway: the need for isogenes in Arabidopsis thaliana

The aspartate‐derived amino acid pathway in plants is an intensively studied metabolic pathway, because of the biosynthesis of the four essential amino acids lysine, threonine, isoleucine and methionine. The pathway is mainly controlled by the key regulatory enzymes aspartate kinase (AK; EC 2.7.2.4), homoserine dehydrogenase (HSDH; EC 1.1.1.3) and 4‐hydroxy‐tetrahydrodipicolinate synthase (EC 4.3.3.7), formerly referred to as dihydrodipicolinate synthase (DHDPS). They are encoded by isoenzyme families and it is not known why such families are evolutionarily maintained. To gain more insight into the specific roles and regulation of the isoenzymes, we inhibited DHDPS in Arabidopsis thaliana with the chemical compound (N,N‐dimethylglycinatoboranyloxycarbonylmethyl)‐dimethylamine‐borane (DDAB) and compared the short‐term effects on the biochemical and biomolecular level to the long‐term adaptations in dhdps knockout mutants. We found that DHDPS2 plays a crucial role in controlling lysine biosynthesis, thereby stabilizing flux through the whole aspartate pathway. Moreover, DHDPS2 was also shown to influence the threonine level to a large extent. In addition, the lysine‐sensitive AKs, AKLYS1 and AKLYS3 control the short‐ and long‐term responses to perturbed lysine biosynthesis in Arabidopsis thaliana.     

Application of a high-throughput HPLC-MS/MS assay to Arabidopsis mutant screening; evidence that threonine aldolase plays a role in seed nutritional quality

Beyond their essential function as the building blocks of proteins, amino acids contribute to many aspects of plant biochemistry and physiology. Despite this, there are relatively large gaps in our understanding of the biochemical pathways and regulation of amino acid synthesis in plants. A rapid (1.5 min versus 20-90 min for standard methods) HPLC-MS/MS assay for separating 19 amino acids was developed for quantifying levels of free amino acids in plant tissue. This assay was used to determine the free amino acid content in the seeds of 10,000 randomly mutagenized Arabidopsis lines, and 322 Arabidopsis lines with increased levels of one or more amino acids were identified. The heritability of the mutant phenotype was confirmed for 43 lines with increased seed levels of the aspartate-derived amino acids Ile, Lys, Thr, or Met. Genetic mapping and DNA sequencing identified a mutation in an Arabidopsis threonine aldolase (AT1G08630, EC 4.1.2.5) as the cause of increased seed Thr levels in one mutant. The assay that was developed for this project has broad applicability to Arabidopsis and other plant species.     

Genetic and amino-acid analysis of two maize threonine-overproducing,lysine-insensitive aspartate kinase mutants

The aspartate-derived amino-acid pathway leads to the production of the essential amino-acids lysine, methionine, threonine and isoleucine. Aspartate kinase (AK) is the first enzyme in this pathway and exists in isoforms that are feedback inhibited by lysine and threonine. Two maize (Zea mays L.) threonine-overproducing, lysine-insensitive AK mutants (Ask1-LT19 and Ask2-LT20) were previously isolated. The present study was conducted to determine the map location of Ask2 and to examine the amino-acid profiles of the Ask mutants. The threonine-overproducing trait conferred by Ask2-LT20 was mapped to the long arm of chromosome 2. Both mutants exhibited increased free threonine concentrations (nmol/mg dry weight) over wild-type. The percent free threonine increased from approximately 2% in wild-type kernels to 37–54% of the total free amino-acid pool in homozygous mutant kernels. Free methionine concentrations also increased significantly in homozygous mutants. Free lysine concentrations were increased but to a much lesser extent than threonine or methionine. In contrast to previous studies, free aspartate concentrations were observed to decrease, indicating a possible limiting factor in threonine synthesis. Total (free plus protein-bound) amino-acid analyses demonstrated a consistent, significant increase in threonine, methionine and lysine concentrations in the homozygous mutants. Significant increases in protein-bound (total minus free) threonine, methionine and lysine were observed in the Ask mutants, indicating adequate protein sinks to incorporate the increased free amino-acid concentrations. Total amino-acid contents (nmol/kernel) were approximately the same for mutant and wild-type kernels. In five inbred lines both Ask mutations conferred the threonine-overproducing phenotype, indicating high expressivity in different genetic backgrounds. These analyses are discussed in the context of the regulation of the aspartate-derived amino-acid pathway.